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I have a program that is finding paths in a graph and outputting the cumulative weight. All of the edges in the graph have an individual weight of 0 to 100 in the form of a float with at most 2 decimal places.

On Windows/Visual Studio 2010, for a particular path consisting of edges with 0 weight, it outputs the correct total weight of 0. However on Linux/GCC the program is saying the path has a weight of 2.35503e-38. I have had plenty of experiences with crazy bugs caused by floats, but when would 0 + 0 ever equal anything other than 0?

The only thing I can think of that is causing this is the program does treat some of the weights as integers and uses implicit coercion to add them to the total. But 0 + 0.0f still equals 0.0f! As a quick fix I reduce the total to 0 when less then 0.00001 and that is sufficient for my needs, for now. But what vodoo causes this?

NOTE: I am 100% confident that none of the weights in the graph exceed the range I mentioned and that all of the weights in this particular path are all 0.

EDIT: To elaborate, I have tried both reading the weights from a file and setting them in the code manually as equal to 0.0f No other operation is being performed on them other than adding them to the total.

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19  
Can you construct a minimal test-case? –  Oliver Charlesworth Apr 24 '12 at 18:22
3  
How are you confirming that the weights are actually zero in your test case? The ultimate test would be print and check their binary representation in hex, or perhaps do assert(weight == 0.0f). –  Emile Cormier Apr 24 '12 at 18:36
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Let's accept that x * 0 == 0 for all x. If sum(xi) != 0, then there exists xi != 0. This can be proven by taking the contra-positive. I've therefore proven mathematically that one of the weights is actually not zero. :P –  Emile Cormier Apr 24 '12 at 19:00
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I'd bet one cent that you are adding at least one uninitialized variable. –  rodrigo Apr 24 '12 at 19:09
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@AustinHenley - Uninitialized floats tend to have a null exponent and that gives them a value in the order of 1e-40 - 1e-30. If you have any other non-null value in the path, then the uninitialized one would be negligible. –  rodrigo Apr 24 '12 at 23:09

3 Answers 3

up vote 11 down vote accepted

Because it's an IEEE floating point number, and it's not exactly equal to zero.

http://www.cygnus-software.com/papers/comparingfloats/comparingfloats.htm

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But the question is: why? (as in, why is it not zero?) However, that's not possible to answer (yet), because we need to see a test-case from the OP. –  Oliver Charlesworth Apr 24 '12 at 18:29
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Zero can be represented exactly in IEEE floats, so what baffles me is why arithmetic with only zeroes leads to a non-zero result. –  Emile Cormier Apr 24 '12 at 18:32
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@DavidTitarenco I think your comment might be the truth, but dyffymo's answer is just too generic. –  Ziyao Wei Apr 24 '12 at 18:33
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@Austin Henley: To clarify 0 + 0 is never anything other than 0 if by all 0s in the equation you mean 0x00000000. You're just doing something wrong. In the best case scenario, you're invoking unspecified behavior somewhere else in your code. –  David Titarenco Apr 24 '12 at 18:38
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I believe the compiler - if it says 0 + 0 + 0 != 0, then one of those zeroes isn't. –  duffymo Apr 24 '12 at 19:05

[...] in the form of a float with at most 2 decimal places.

There is no such thing as a float with at most 2 decimal places. Floats are almost always represented as a binary floating point number (fractional binary mantissa and integer exponent). So many (most) numbers with 2 decimal places cannot be represented exactly.

For example, 0.20f may look as an innocent and round fraction, but

printf("%.40f\n", 0.20f);

will print: 0.2000000029802322387695312500000000000000.

See, it does not have 2 decimal places, it has 26!!!

Naturally, for most practical uses the difference in negligible. But if you do some calculations you may end up increasing the rounding error and making it visible, particularly around 0.

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I was aware of this for nonzero values, but my problem is arising when dealing with only 0s. However, for a large number of zeros being slightly off, maybe that is causing the problem as pointed out in another answer. –  Austin Henley Apr 24 '12 at 18:35
    
And how do you know that you are dealing exactly with 0's? Are they compiler constants? Read from a file? –  rodrigo Apr 24 '12 at 18:37
    
I tried using constants and reading from a file. –  Austin Henley Apr 24 '12 at 18:37

It may be that your floats containing values of "0.0f" aren't actually 0.0f (bit representation 0x00000000), but a very, very small number that evaluates to about 0.0. Because of the way IEEE754 spec defines float representations, if you have, for example, a very small mantissa and a 0 exponent, while it's not equal to absolute 0, it will round to 0. However, if you add these numbers together a sufficiently number of times, the very small amount will accumulate into a value that eventually will become non-zero.

Here is an example case which gives the illusion of 0 being non-zero:

float f = 0.1f / 1000000000;
printf("%f, %08x\n", f, *(unsigned int *)&f);
float f2 = f * 10000;
printf("%f, %08x\n", f2, *(unsigned int *)&f2);

If you are assigning literals to your variables and adding them, though, it is possible that either the compiler is not translating 0 into 0x0 in memory. If it is, and this still is happening, then it's also possible that your CPU hardware has a bug relating to turning 0s into non-zero when doing ALU operations that may have squeaked by their validation efforts.

However, it is good to remember that IEEE floating point is only an approximation, and not an exact representation of any particular float value. So any floating-point operations are bound to have some amount of error.

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No, this is nothing like my case. I am NOT dividing, ever. I am only assigning 0 and 0.0f to variables and then adding them. –  Austin Henley Apr 24 '12 at 18:40
    
I am giving an example of what may cause the illusion. Of course, many different situations could cause something similar. –  Ben Richards Apr 24 '12 at 18:41
    
Right, I just never thought that adding constant 0s could cause this. –  Austin Henley Apr 24 '12 at 18:42
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@sidran32: Whilst it's possible, it's vanishingly unlikely, when compared to all the other potential causes... –  Oliver Charlesworth Apr 24 '12 at 18:53
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@OliCharlesworth Of course. But if he ruled out everything else, it can end up being the ultimate reason. Back in high school I uncovered a CPU bug in a similar manner in my C++ class (confirmed by my teacher at the time). It sounded like he was nearing confidence that his code was unambiguous enough that other causes were likely ruled out. That's why I mentioned it. –  Ben Richards Apr 24 '12 at 19:02

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